Demonstration of Polymer Photodegradation Using a Simple Apparatus

Demonstration Cite This: J. Chem. Educ. XXXX, XXX, XXX−XXX

pubs.acs.org/jchemeduc

Demonstration of Polymer Photodegradation Using a Simple Apparatus Thiago A. Cacuro, Amanda S. M. Freitas, and Walter R. Waldman* Universidade Federal de São Carlos, Campus SorocabaRodovia João Leme dos Santos (SP-264), km 100, Sorocaba/SP 18052-780, Brazil

Downloaded via UNIV OF TEXAS AT EL PASO on October 22, 2018 at 13:40:24 (UTC). See https://pubs.acs.org/sharingguidelines for options on how to legitimately share published articles.

S Supporting Information *

ABSTRACT: Polymer science is widely used in industry, from the development of packaging to the process for obtaining products of all kinds. Despite this omnipresence in the productive sector and our daily lives, topics related to polymer science are not as representative in school curricula. The demonstrations developed in this work address some technological applications of photodegradation, such as the functionalization of nonpolar polymer surfaces to receive water-based paints, and their participation in the deterioration of polymers exposed to the weather. The simplicity and easy-to-make characteristics of the proposed experiments make them eligible to facilitate the discussion of polymer science topics in the classroom.

KEYWORDS: High School/Introductory Chemistry, Upper-Division Undergraduate, Graduate Education/Research, Demonstrations, Polymer Chemistry, Materials Science, Photochemistry

P

Polymer photodegradation has some peculiarities to be highlighted:

hotodegradation of polymeric materials is not an issue with a recent birth date. The first modern report of studies in this area was published in 1861 when Hoffman studied the role of oxygen in the degradation of gutta-percha.1 In 1917, the influence of light on the degradation of polymers was recorded in the scientific literature with studies of natural rubber solutions exposed to UV radiation.2 Since then, much progress has been made in understanding the mechanisms that lead to the degradation of a polymeric material, with the construction of a general self-catalytic cycle for oxidative degradation (Figure 1A) that fits fully or partially to most of the polyolefins found in our daily lives. The self-catalytic cycle starts with a radical formation through some energy input, usually heat, shearing, or light. The radicals pass through a sequence of reactions forming various polar chemical groups such as hydroperoxides, hydroxyls, and carbonyls, reaching the breakdown of the polymer chain, causing the reduction of its molecular weight (Figure 1C), or the cross-linking of the polymer chain, producing the opposite effect, the increase of molecular weight (Figure 1B). In the literature, there are several references that allow a deeper understanding of the subject.3−7 The field of polymer degradation research is divided into categories according to the degradative environments, such as photodegradation (mainly caused by light radiation), thermooxidative degradation (caused by heat in the presence of oxygen), thermo-mechanical degradation (caused by heat under shear), and thermal degradation (caused by heat in an inert or rarefied atmosphere), among others. © XXXX American Chemical Society and Division of Chemical Education, Inc.

• Photodegradation depends on the presence of light and oxygen, and both have limited diffusion through the polymer bulk; therefore, in general, photodegradation is a surface phenomenon, with a diminished effect as a function of depth in the polymer.8 • One of the main consequences of photodegradation is the formation and increase of crystalline domains. This occurs because of two factors: (1) chain scission, leading to an increased mobility of the polymer chains which can make part of the crystalline domains, and (2) formation of polar groups, which makes the chains closer by intermolecular attraction, called chemocrystallization.9 This increase in crystalline domains leads to a decrease of volume and the formation of cracks in the surface (Figure 2). • The absorption of light radiation does not occur in any chemical structure, requiring the presence of chromophore groups that absorb the incident energy and initiate the photochemical degradation reactions. Usually, chromophore groups are carbonyls and carbon−carbon double bonds. Polymers without chromophore groups in the intrinsic structure can also photodegrade because of defects in the polymer chain during its synthesis or Received: November 1, 2017 Revised: September 14, 2018

A

DOI: 10.1021/acs.jchemed.7b00836 J. Chem. Educ. XXXX, XXX, XXX−XXX

Journal of Chemical Education

Demonstration

Figure 1. (A) Representation of the general self-catalytic cycle for oxidative degradation for polyolefins. (B) Representation of the cross-linking reactions, which cause the increase in the molecular weight. (C) Representation of the Norrish reaction, which causes the decrease of the molecular weight.

Figure 2. Micrographies of the photodegraded polypropylene surface for 196 h under the same conditions of the proposed experiment in this paper, in magnification of 500 (left), 2,000 (center), and 20,000 (right) times. The bars in the bottom right of each micrography represent 200 μm (left), 50 μm (center), and 5 μm (right).

uncovered region. The material was exposed up to 3 days in a photodegradation chamber, removed, and tested for wettability, mechanical resistance, and brittleness/opacity. Another experiment was performed with a polypropylene piece with a barrier for light, which was shifted every day to the left, so after 3 days, the polypropylene piece had four different strips with three, two, one, and zero days of exposure (Figure 3). After exposure the part was cut, separating the different strips.

degradation in processing before commercialization can generate chromophore groups in some points of the chain in enough of a quantity to absorb energy from light and carry on the photodegradation reactions.4 Another example of polymer photodegradation involving chromophores is paper yellowing, a problem tackled by conservators.10 • Permeation of oxygen through the bulk is dependent on the morphology of the material. Prevalence of amorphous domains leads to higher oxygen permeation through the polymer, while the prevalence of crystalline domains has the opposite effect. In this paper we propose experiments in the framework of photodegradation to show the advantages (improving the wettability to receive water-based inks),11 and the disadvantages that come together, like losing mechanical properties and increasing the opacity and brittleness of the photodegradation.

■

METHODOLOGY Simple tests were conducted to demonstrate the effects of photodegradation in polymers, without the need for sophisticated analytical equipment. A common polypropylene folder was used, but any polypropylene foldable material can be used. Packaging films with a reduced thickness can bend or deform during exposure to UV radiation and make the suggested tests difficult, so thin parts should be avoided, less than 0.2 mm thick. Experiments were performed by exposing to UV radiation (details in the Supporting Information) a piece of folder partially covered to promote photodegradation only in the

Figure 3. Picture of the polypropylene piece assembled to have different days of photodegradation in the same part. The numbers on the top of each strip represent the number of days of photodegradation of that strip.

For the wettability test, the piece was wetted with a solution of blue dye, to facilitate visualization, and the behavior of water on the surface was observed. Also, for wettability, a disposable cup of polystyrene was exposed to UV light for 3 h, and the result was followed by pouring some amount of water from a pristine and a degraded disposable cup. B

DOI: 10.1021/acs.jchemed.7b00836 J. Chem. Educ. XXXX, XXX, XXX−XXX

Journal of Chemical Education

Demonstration

phenomenon is used in the industry for the preparation of films and parts for receiving water-based paints. This behavior of wettability change can already be observed before the polypropylene surface begins to become opaque due to the crystallinity increase on the surface. Figure 5 shows some pictures of disposable cups, made of polystyrene, in different moments of pouring water. The

For mechanical resistance, each of the strips of the polypropylene piece (Figure 3) was folded in the middle to observe the color change in the fold, and, if the strips break after one or more folds, to test fatigue properties. For opacity and brittleness, a figure in the form of heart, made of paperboard to prevent the passage of light, was cut and placed as a barrier to light, to provide contrast between degraded and nondegraded regions. We performed this demonstration in four classes (three undergrad courses and one graduate course), with 25 students in average, in the second semester of 2017. Each demonstration was preceded by an exposition (25−30 min average) about polymer fundamentals and its photodegradation. The efficacy of the demonstration was evaluated by using a pre- and a postquestionnaire, which are also available in the Supporting Information.

■

HAZARDS Preparation of degraded samples must be performed with attention to the hazards of UV light. The teacher must wear goggles and a lab coat, and nobody can ever look directly at or expose the skin to the UV lamp, so the photodegradation chamber must be closed whenever it is on. UV photodegradation in the presence of oxygen generates ozone, so the photodegradation must be performed in the fume hood.

■

DISCUSSION

Wettability

Figure 4 shows the polypropylene sample that was partially covered and exposed for 3 days to UV light (Figure 4A,C) and Figure 5. Pictures of a pristine disposable cup (left) and a photodegraded disposable cup (right) in different moments of pouring water (the higher the picture, the sooner the moment). Pictures at the bottom are magnifications of inside the cup after water is poured.

pristine disposable cup (Figure 5, left) shows evident hydrophobic behavior, with a low interaction with water and almost no sign of water after water is poured (Figure 5, bottom left). The same brand of this disposable cup was kept under UV light for 3 h and showed hydrophilic behavior (Figure 5, right), with the presence of water keeping the surface wet at the end of the experiment (Figure 5, bottom right). In the prequestionnaire, most students already had a notion of the greater or lesser interaction of water with certain surfaces, such as plant leaves. However, the majority could not adequately explain the phenomenon, with a success rate of 20−50%, depending on the class. The practical demonstration and the theoretical and practical discussions helped to consolidate the concepts and the chemical processes involved in this phenomenon, increasing the success rate to 100% in this topic. It is important to note that this experiment is related to the wettability influenced by the surface polarity, and it is not possible to use this experiment to address all the variables that can affect this property.

Figure 4. Dry PP samples partially degraded (A and C) and the same PP samples wetted with blue dye solution (B and D).

the same samples after being wetted by an aqueous solution of blue dye (Figure 4B,D). As the polypropylene surface is hydrophobic, it is expected that water does not wet its surface, which indeed happened in the covered parts of the polypropylene piece of the folder, while the exposed portions were wetted by the aqueous solution of blue dye (Figure 4B,D). The observed behavior took place because of the formation of polar groups such as hydroxyl and carbonyl during the photodegradation. These chemical groups decrease the surface energy and provide sites for intermolecular interaction with water by hydrogen bonds. This experiment proved the concept of converting the hydrophobic surface to hydrophilic.12 This

Brittleness

Figure 6 shows some pieces of a polypropylene folder, with different patterns for the cover, after folding. It can be highlighted that breaking happens only in the photodegraded regions at the same time as nonphotodegraded areas are C

DOI: 10.1021/acs.jchemed.7b00836 J. Chem. Educ. XXXX, XXX, XXX−XXX

Journal of Chemical Education

Demonstration

without these boundaries, they are transparent, while the increase in crystalline content increases its opacity. The demonstration was successful in constructing the association between opacity and the increase in crystallinity after photodegradation, since no one had mentioned this association in the prequestionnaire. Some students even managed to associate the opacity with the degradation of the material in the prequestionnaire, although they could not explain the reason properly. In the postquestionnaire, all students were able to associate opacity with crystallinity. Variation of Volume

An unplanned part of the demonstration, which was therefore not included in the questionnaires, was the bending of the tips of the square pieces exposed to photodegradation (Figure 8).

Figure 6. Pieces of polypropylene folder with different patterns of photodegradation after 3 days of photodegradation while partially covered. Above: PP photodegraded sample folded in half. Below: PP sample photodegraded with a photomask with a heart-shaped hole in the middle.

preserved after folding. This behavior is due to the loss of mechanical properties after exposure to UV radiation because of the crystallization processes on the surface, leading to irreversible changes after mechanical stimuli. Figure 7 shows a cell-phone picture with the details students can observe after folding the samples illustrated in Figure 3,

Figure 8. Pictures of a photodegraded square piece with the tips bent.

In the collective discussion with the classes, all students could reach the correct conclusion that the decrease of volume in the surface of the photodegraded material, caused by its crystallization, is responsible for the folding of the pieces upward. The way the tips of the square pieces folded after exposure to photodegradation (Figure 7) helped in the collective discussion and the visualization of the decrease of volume as a function of the increase in crystallinity. In the collective discussion, the students always came to the correct conclusion that the reduction in the volume of the surface of the photodegraded material, caused by its crystallization, is responsible for the folding of the pieces upward, causing the majority to answer the postquestionnaire regarding this theme correctly. This part of the demonstration also consolidated the fact that photodegradation is a surface phenomenon. We tried to repeat this phenomenon without the obstacle in the center of the plastic piece, and the result varied, sometimes folding up and others down, probably because of the presence of tension that originated during the polymer processing, so the blocking in the center has a functional role in the phenomenon.

Figure 7. Cell-phone picture of the folding made in strips of PP with different times of photodegradation.

highlighting the difference in resistance as a function of photodegradation time. In the prequestionnaire, the majority of students related the loss of mechanical property with exposure to sunlight, heat, and temperature variation, but no one associated it with crystallization. In the postquestionnaire, a good number of the students were able to link the decrease of mechanical properties to crystallization, but there was still difficulty in explaining the process of crystallization. This part of the demonstration was useful as an informative process but was deficient in making the students understand the phenomenon.

■

SUGGESTIONS FOR IMPROVEMENT As alternatives for this experiment proposal, teachers can engage students using an investigative approach. Students could bring different identified materials (e.g., using recycling symbols for that) and test the distinct sensitivity to UV light exposure. With the results and the support of a mentor with knowledge of polymer science, students could investigate the reasons behind the behavior of the polymers after degradation. For example, two products of the same polymer, one of which is sold for outdoor use and the other for indoor use, are likely to have different formulations of stabilizers, and therefore different results after the same photodegradation time. Another suggested approach would be testing different waste plastic materials commonly found on the street, because of waste mismanagement, and accelerating their degradation to produce

Opacity

The same samples made to monitor changes in wettability (Figure 4) and brittleness (Figure 6) can be used to verify the differences in opacity as a function of photodegradation time. For polymers, the refraction index rules the degree of interaction with the light. As crystals and amorphous domains have different refraction indexes, light can disperse because of the boundaries between crystalline and amorphous domains. Because of that, polymers are predominantly amorphous; D

DOI: 10.1021/acs.jchemed.7b00836 J. Chem. Educ. XXXX, XXX, XXX−XXX

Journal of Chemical Education

Demonstration

(4) Billingham, N. C.; Calvert, P. D. The Degradation and Stabilisation of PolyolefinsAn Introduction. In Degradation and Stabilisation of Polyolefins; Allen, N. S., Ed.; Applied Science Publishers: Essex, 1983; pp 1−28. (5) Krebs, F. C. Stability and Degradation of Organic and Polymer Solar Cells; John Wiley & Sons Ltd.: Hoboken, NJ, 2012; p 360. ́ (6) De Paoli, A. M. Degradaçaõ e Estabilizaçaõ de Polimeros; Artliber Editora: São Paulo, 2009; p 286. (7) Compton, R. G.; Bamford, C. H.; Tipper, C. F. H. Degradation of Polymers, 14th ed.; Elsevier Scientific Publishing Company: New York, 1975; pp 1−561. (8) Yousif, E.; Haddad, R. Photodegradation and photostabilization of polymers, especially polystyrene: review. SpringerPlus 2013, 2, 398. (9) Rabello, M. S.; White, J. R. Crystallization and melting behaviour of photodegraded polypropylene− 1. Chemi-crystallization. Polymer 1997, 38 (26), 6379−6387. (10) Seery, M. Paper conservation. Education in Chemistry; March 1, 2013. Accessed in https://eic.rsc.org/feature/paper-conservation/ 2020204.article (accessed Sep 2018). (11) Rentzhog, M.; Fogden, A. Print quality and resistance for waterbased flexography on polymer-coated boards: Dependence on ink formulation and substrate pretreatment. Prog. Org. Coat. 2006, 57, 183−194. (12) Blais, D.; Carlsson, D. J.; Wiles, D. M. Surface changes during polypropylene photo-oxidation: a study by infrared spectroscopy and electron microscopy. J. Polym. Sci., Part A-1: Polym. Chem. 1972, 10 (4), 1077−1092.

microplastics to check their properties. It is possible to check, for instance, the buoyancy in water, which can be positive (microplastics float), negative (microplastics sink), or neutral (microplastics oscillates with the water turbulence). Determining the buoyancy allows us to discuss if the microplastics generated from different materials in the accelerated photodegradation will potentially affect the benthonic species in the bottom or fishes and other species on the superior part of a water body.

■

CONCLUSIONS The set of demonstrations proposed here can be easily performed by using low-cost materials that are easy to access, besides allowing the approach to several technical aspects of the degradation of the polymers. By being very visual and hands-on, the demonstrations make tangible some subjects that require some abstraction, helping to consolidate the theoretical concepts involved. The demonstration proved to be valid for the teaching of polymeric photodegradation, since it can bring a theoretical foundation associated with a very visual experimental part.

■

ASSOCIATED CONTENT

* Supporting Information S

The Supporting Information is available on the ACS Publications website at DOI: 10.1021/acs.jchemed.7b00836. Prequestionnaire (PDF, DOCX) Postquestionnaire (PDF, DOCX) Dimensions and details of the photodegradation chamber (PDF, DOCX) Description of student understanding of other properties such as wettability (PDF, DOCX)

■

AUTHOR INFORMATION

Corresponding Author

*E-mail: [email protected]. ORCID

Thiago A. Cacuro: 0000-0003-4436-7691 Walter R. Waldman: 0000-0002-7280-2243 Notes

The authors declare no competing financial interest.

■

ACKNOWLEDGMENTS The authors acknowledge the Department of Chemistry, Physics, and Mathematics for granting the use of a teaching laboratory for the development of the experiments. W.R.W. acknowledges the Fundaçaõ de Apoio à Pesquisa do Estado de São Paulo (Fapesp) for Grant 2016/24-936-3, and T.A.C. and A.S.M.F., respectively, acknowledge the Coordenação de ́ Superior (Capes) for Aperfeiçoamento de Pessoal de Nivel fellowships.

■

REFERENCES

(1) Hofmann, W. A. J. Chem. Soc. 1861, 13, 51. (2) Indian Rubber J. 1917, 54, 688; Chem. Abstr. 1918, 12, 322 apud ́ De Paoli, M. A. A foto-oxidaçaõ da borracha de butadieno. Quimica Nova 1983, 6, 140−148. (3) Celina, M. C.; Billingham, N. C.; Wiggins, J. S. Polymer Durability and Radiation Effects; ACS Symposium Series 978; Oxford University Press: Washington, DC, 2007; p 366. E

DOI: 10.1021/acs.jchemed.7b00836 J. Chem. Educ. XXXX, XXX, XXX−XXX